CN220534135U

CN220534135U - Battery module clamping platform

Info

Publication number: CN220534135U
Application number: CN202322100270.7U
Authority: CN
Inventors: 请求不公布姓名
Original assignee: Jiangsu Fenghesheng Intelligent Technology Co ltd
Current assignee: Jiangsu Fenghesheng Intelligent Technology Co ltd
Priority date: 2023-08-07
Filing date: 2023-08-07
Publication date: 2024-02-27
Anticipated expiration: 2033-08-07

Abstract

The utility model provides a battery module clamping platform.A tray clamping hand for clamping a battery core tray and a module clamping hand for clamping a battery module are integrally arranged on a clamping frame, and the tray clamping hand and the module clamping hand are used for clamping the battery module tray together; the clamping frame is provided with the transverse linear moving mechanism and the longitudinal linear moving mechanism, so that the clamping positions of the module clamping hands can be adjusted transversely and longitudinally in the horizontal plane, and the purpose of compatibility of battery modules with different specifications is achieved. The utility model has simple and compact structure and can rapidly and stably fulfill the aim of clamping the battery module.

Description

Battery module clamping platform

Technical Field

The utility model relates to material clamping equipment, in particular to a battery module clamping platform.

Background

In the production process of the battery module, the whole of the module and the tray is often required to be processed, and the clamping equipment plays roles of positioning and stabilizing in the processing process.

The clamping devices in the prior art are mostly directed to fixed point positioning of the tray without positioning the mould. Therefore, when executing specific instructions such as transferring and turning, additional equipment is needed to be added to take out the module from the tray, and the module is then loaded into the tray after the transferring and turning are completed. Some manufacturers are also provided with clamping devices on two sides of the module, but most modules with single models are designed, and the modules are required to be specially made with matching components corresponding to the clamping devices, so that the structure is complex and the compatibility is poor.

Disclosure of Invention

The utility model aims to provide a battery module clamping platform which comprises a clamping frame, and a module clamping mechanism and a tray clamping mechanism which are arranged on the clamping platform;

the clamping frame is square, the tray clamping mechanism comprises two groups of tray clamping hands which are oppositely arranged on the side edges of the clamping frame, and the module clamping mechanism comprises two groups of module clamping hands which are positioned on the two sides of the clamping frame;

the device also comprises an X-axis linear module and a Y-axis linear module for servo adjustment of the horizontal plane position of the clamping hand of the module.

Further, the X-axis linear modules are positioned at two ends of the clamping frame, and the X-axis linear modules are provided with connecting plates for supporting the Y-axis linear modules; the X-axis linear module drives the connecting plate and the Y-axis linear module on the connecting plate to move along the direction of clamping the battery module;

the module tong is arranged on the Y-axis linear module, and the Y-axis linear module drives the module tong to move along the connecting plate.

Further, the X-axis linear module comprises X-direction guide rails arranged at two ends of the clamping frame, X-direction sliding blocks slidably mounted on the X-direction guide rails, and push-pull electric cylinders arranged along the extending direction of the X-direction guide rails; the end part of the connecting plate is connected with the X-direction sliding block and is connected with an output shaft of the push-pull electric cylinder.

Further, the Y-axis linear module comprises a Y-direction guide rail arranged on the connecting plate and a Y-direction screw rod arranged along the extending direction of the Y-direction guide rail, and the module clamping hand is connected with the Y-direction guide rail in a sliding manner and is connected with the Y-direction screw rod through a ball screw rod structure; and the end part of the Y-direction lead screw is connected with a servo motor.

Further, the tray clamping hand comprises two groups of half molds which are oppositely arranged in the vertical direction, and two sides of each half mold are provided with a clamping plate for supporting the half mold;

the half mould comprises a fixed block and a clamping block arranged on the fixed block, and a channel for the clamping block to pass through is arranged on the fixed block;

the rear end of the fixed block is fixed with a driving cylinder, and an output shaft of the driving cylinder is connected with the clamping block.

Further, a positioning cylinder is further arranged on the pressing plate, and locking holes for the output shafts of the positioning cylinders to extend in are formed in the side walls of the fixed block and the clamping block.

Further, the module tong includes the backup pad and locates the flexible briquetting in the backup pad, vertically be provided with Z in the backup pad to the guide rail, flexible briquetting is installed on the slider of Z to the guide rail to can follow Z guide rail vertical movement.

Further, a transmission mechanism for driving the flexible pressing block to vertically move is further arranged, the transmission mechanism comprises a driving part, a lever part and a pressing part, the driving part comprises a pushing cylinder arranged on the supporting plate, an output shaft of the pushing cylinder is connected with a pushing plate, and the outer end face of the pushing plate is an inclined face with inclination;

the pressing part comprises a pressing block arranged at the rear end of the flexible pressing block, and the pressing block is connected with the flexible pressing block through a pressing block mounting seat;

the lever part comprises a rotating arm, a rotating shaft is arranged on the rotating arm, and the rotating shaft is rotatably connected to the supporting plate;

two ends of the rotating arm are respectively contacted with the end face of the press-fitting block and the inclined face of the pushing plate.

Further, a reset spring is arranged at the bottom of the press-fit block, and the other end of the reset spring is fixedly connected with the supporting plate.

Further, a positioning pin is arranged on the inner side of the reset spring, and a positioning hole for positioning the positioning pin is formed in the bottom of the press-fit block.

The utility model integrates a tray clamping hand for clamping the battery cell tray and a module clamping hand for clamping the battery module on one clamping frame, and clamps the battery module tray through the tray clamping hand and the module clamping hand together; the clamping frame is provided with the transverse linear moving mechanism and the longitudinal linear moving mechanism, so that the clamping positions of the module clamping hands can be adjusted transversely and longitudinally in the horizontal plane, and the purpose of compatibility of battery modules with different specifications is achieved. The utility model has simple and compact structure and can rapidly and stably fulfill the aim of clamping the battery module.

Drawings

Fig. 1 is a schematic structural view of a battery module clamping platform according to the present utility model;

fig. 2 is a top view of the battery module clamping platform of the present utility model;

FIG. 3 is a schematic structural view of an X-axis linear module;

FIG. 4 is a schematic diagram of a Y-axis linear module;

FIG. 5 is a schematic view of the structure of a pallet clamp;

FIG. 6 is an exploded view of the pallet clamp;

FIG. 7 is a schematic view of a module clip;

FIG. 8 is a side view of a modular grip;

fig. 9 is a schematic diagram of the connection of the return spring to the press-fit block.

Reference numerals: a clamping frame 1; a pallet grip 2; a module clamping hand 3; an X-axis linear module 4; a Y-axis linear module 5; a connection plate 6;

a fixed block 201; a clamp plate 202; a clamp block 203; a channel 204; a driving cylinder 205; a positioning cylinder 206; a lock hole 207; a sensor 208;

a support plate 301; a flexible press block 302; a Z-guide rail 303; a pushing cylinder 304; a push plate 305; an inclined surface 306; a press-fitting block 307; a press block mount 308; a rotation arm 309; a rotation shaft 310; a roller 311; a return spring 312; a positioning pin 313; a positioning hole 314;

an X-guide rail 41; an X-direction slider 42; push-pull electric cylinder 43;

a Y-guide rail 51; a Y-direction lead screw 52; a servo motor 53.

Detailed Description

The battery module clamping platform as shown in fig. 1 and 2 comprises a clamping frame 1, and a module clamping mechanism and a tray clamping mechanism which are arranged on the clamping platform;

the clamping frame 1 is square, tray fixture is including setting up in two sets of tray tong 2 of clamping frame 1 side relatively, module fixture is including being located two sets of module tong 3 of clamping frame 1 both sides, tray tong 2 and module tong 3 carry out the centre gripping from the both sides of module tray and battery module respectively. The clamping direction of the tray clamping hand 2 and the module clamping hand 3 is taken as an X axis, the horizontal direction vertical to the X axis is taken as a Y axis, and the device further comprises an X-axis linear module 4 and a Y-axis linear module 5 for servo-adjusting the horizontal plane position of the module clamping hand 3 according to the specifications of different battery modules; the X-axis linear modules 4 are positioned at two ends of the clamping frame 1, the X-axis linear modules 4 are provided with connecting plates 6 for supporting the Y-axis linear modules 5, and the connecting plates 6 and the Y-axis linear modules 5 on the connecting plates 6 are driven by the X-axis linear modules 4 to move along the direction of clamping the battery modules; the module clamp 3 is arranged on the Y-axis linear module 5, and the Y-axis linear module 5 drives the module clamp 3 to move along the Y direction of the connecting plate 6. In the whole clamping process, the tray clamping hand 2 fixes the position of the tray, and the module clamping hand 3 performs servo adjustment through the X-axis linear module 4 and the Y-axis linear module 5 so as to clamp battery modules with different specifications.

As shown in fig. 3, the X-axis linear module 4 includes X-direction guide rails 41 provided at both ends of the clamping frame 1, X-direction sliders 42 slidably mounted on the X-direction guide rails 41, and push-pull cylinders 43 provided along the extending direction of the X-direction guide rails 41; the end of the connecting plate 6 is connected with the X-direction sliding block 42 and is connected with the output shaft of the push-pull electric cylinder 43, and the connecting plate 6 moves along the X-direction guide rail 41 under the drive of the stroke of the push-pull electric cylinder 43.

As shown in fig. 4, the Y-axis linear module 5 includes a Y-directional guide rail 51 disposed on the connection plate 6, and a Y-directional screw 52 disposed along the extending direction of the Y-directional guide rail 51, and the module clamping hand 3 is slidably connected to the Y-directional guide rail 51 and connected to the Y-directional screw 52 through a ball screw structure; the end part of the Y-direction lead screw 52 is connected with a servo motor 53, and the servo motor 53 transmits rotary power to the Y-direction lead screw 52 to drive the module clamping hand 3 to move along the Y-direction guide rail 51.

As shown in fig. 5 and 6, the tray gripper 2 includes two sets of half molds oppositely arranged in a vertical direction and pinch plates 202 arranged at two sides of the half molds, and the pinch plates 202 can provide support for the two half molds; the half molds comprise fixed blocks 201 and clamping blocks 203 arranged on the fixed blocks 201, the fixed blocks 201 are used for limiting the positions of the clamping blocks 203, the clamping blocks 203 on two groups of opposite half molds can limit the upper end face and the lower end face of the side part of the tray, and the fixed blocks 201 are provided with channels 204 for the clamping blocks 203 to pass through; a driving cylinder 205 is fixed at the rear end of the fixed block 201, and an output shaft of the driving cylinder 205 is connected with the clamping block 203, so that the clamping block 203 can reciprocate along the channel 204. The compacting plate 202 is further provided with a positioning cylinder 206, and the side walls of the fixing block 201 and the clamping block 203 are provided with locking holes 207 for the output shafts of the positioning cylinder 206 to extend in. When the positioning cylinder 206 is started, an output shaft of the positioning cylinder 206 extends into the lock hole 207 to lock the position of the clamping block 203; when the output shaft of the positioning cylinder 206 is separated from the lock hole 207, the clamping block 203 can freely move along the channel 204 under the drive of the driving cylinder 205, so as to adjust the position of the clamping tray. In addition, a sensor 208 for monitoring whether the output shaft is in place or not is further arranged on the rear side of the positioning cylinder 206, and the timing of the locking clamp block 203 is adjusted in a servo mode through information fed back by the sensor 208.

As shown in fig. 7 to 9, the module clamping hand 3 includes a support plate 301 and a flexible pressing block 302 disposed on the support plate 301, a Z-direction guide rail 303 is vertically disposed on the support plate 301, and the flexible pressing block 302 is mounted on a slider of the Z-direction guide rail 303 and can vertically move along the Z-direction guide rail 303; the flexible press block 302 is used for applying flexible tightening pressure to the upper end surface of the module and fixing the position of the module by being matched with the tray clamping hand 2. The device is further provided with a transmission mechanism for driving the flexible pressing block 302 to vertically move, the transmission mechanism comprises a driving part, a lever part and a pressing part, the driving part comprises a pushing cylinder 304 arranged on the supporting plate 301, an output shaft of the pushing cylinder 304 is connected with a pushing plate 305, and the outer end surface of the pushing plate 305 is an inclined surface 306 with inclination; the pressing part comprises a pressing block 307 arranged at the rear end of the flexible pressing block 302, and the pressing block 307 is connected with the flexible pressing block 302 through a pressing block mounting seat 308; the lever part comprises a rotating arm 309, a rotating shaft 310 is arranged on the rotating arm 309, and the rotating shaft 310 is rotatably connected to the supporting plate 301, so that two ends of the rotating arm 309 can rotate along the center of the rotating shaft 310; both ends of the rotation arm 309 are respectively in contact with the end face of the press-fitting block 307 and the inclined face 306 of the pressing plate 305. Specifically, the ends of the rotating arm 309 are respectively provided with a roller 311 and contact with the press-fitting block 307 and the pressing plate 305 through the roller 311, so as to enhance the transmission effect of the lever structure.

The rotating arm 309 and the rotating shaft 310 form a lever structure, the pushing cylinder 304 controls the pushing plate 305 to move, one end of the rotating arm 309, which contacts with the pushing plate 305, moves along the inclined surface 306, and the other end of the rotating arm 309 applies a downward force to the press-fitting block 307, so as to drive the flexible pressing block 302 to descend. Further, a return spring 312 is disposed at the bottom of the press-fitting block 307, and the other end of the return spring 312 is fixedly connected to the support plate 301. As flexible press block 302 descends, return spring 312 is in a compressed state; when the pushing cylinder 304 is contracted, the force applied to the press-fitting block 307 by the rotating arm 309 is reduced, and the elastic force of the return spring 312 pushes the rotating arm 309 to move to the initial position. The inner side of the return spring 312 is also provided with a positioning pin 313, the bottom of the press-fitting block 307 is provided with a positioning hole 314 matched with the positioning pin 313, and the positioning pin 313 can position the return spring 312.

While embodiments of the present utility model have been shown and described above, it will be understood that the above embodiments are illustrative and not to be construed as limiting the utility model, and that variations, modifications, alternatives and variations may be made to the above embodiments by one of ordinary skill in the art within the scope of the utility model.

Claims

1. Battery module centre gripping platform, its characterized in that: comprises a clamping frame (1), a module clamping mechanism and a tray clamping mechanism which are arranged on a clamping platform;

the clamping frame (1) is square, the tray clamping mechanism comprises two groups of tray clamping hands (2) which are oppositely arranged on the side edges of the clamping frame (1), and the module clamping mechanism comprises two groups of module clamping hands (3) which are positioned on the two sides of the clamping frame (1);

the device also comprises an X-axis linear module (4) and a Y-axis linear module (5) for servo adjustment of the horizontal plane position of the module clamping hand (3).

2. The battery module clamping platform of claim 1, wherein: the X-axis linear module (4) is arranged at two ends of the clamping frame (1), and a connecting plate (6) for supporting the Y-axis linear module (5) is arranged on the X-axis linear module (4); the X-axis linear module (4) drives the connecting plate (6) and the Y-axis linear module (5) on the connecting plate (6) to move along the direction of clamping the battery module;

the module clamp (3) is arranged on the Y-axis linear module (5), and the Y-axis linear module (5) drives the module clamp (3) to move along the connecting plate (6).

3. The battery module clamping platform of claim 2, wherein: the X-axis linear module (4) comprises X-direction guide rails (41) arranged at two ends of the clamping frame (1), X-direction sliding blocks (42) which are slidably arranged on the X-direction guide rails (41), and push-pull electric cylinders (43) which are arranged along the extending direction of the X-direction guide rails (41); the end part of the connecting plate (6) is connected with the X-direction sliding block (42) and is connected with the output shaft of the push-pull electric cylinder (43).

4. The battery module clamping platform of claim 2, wherein: the Y-axis linear module (5) comprises a Y-direction guide rail (51) arranged on the connecting plate (6) and a Y-direction screw rod (52) arranged along the extending direction of the Y-direction guide rail (51), and the module clamping hand (3) is connected with the Y-direction guide rail (51) in a sliding manner and is connected with the Y-direction screw rod (52) through a ball screw structure; the end part of the Y-direction lead screw (52) is connected with a servo motor (53).

5. The battery module clamping platform of claim 2, wherein: the tray clamp (2) comprises two groups of half molds which are oppositely arranged in the vertical direction, and two sides of each half mold are provided with a clamping plate (202) for supporting the half mold;

the half mould comprises a fixed block (201) and a clamping block (203) arranged on the fixed block (201), wherein a channel (204) for the clamping block (203) to pass through is arranged on the fixed block (201);

the rear end of the fixed block (201) is fixedly provided with a driving cylinder (205), and an output shaft of the driving cylinder (205) is connected with the clamping block (203).

6. The battery module clamping platform of claim 5, wherein: the compression plate (202) is also provided with a positioning cylinder (206), and the side walls of the fixed block (201) and the clamping block (203) are provided with locking holes (207) for the output shafts of the positioning cylinders (206) to extend in.

7. The battery module clamping platform of claim 2, wherein: the module clamp (3) comprises a supporting plate (301) and a flexible pressing block (302) arranged on the supporting plate (301), a Z-direction guide rail (303) is vertically arranged on the supporting plate (301), and the flexible pressing block (302) is arranged on a sliding block of the Z-direction guide rail (303) and can vertically move along the Z-direction guide rail (303).

8. The battery module clamping platform of claim 7, wherein: the device is further provided with a transmission mechanism for driving the flexible pressing block (302) to vertically move, the transmission mechanism comprises a driving part, a lever part and a pressing part, the driving part comprises a pushing cylinder (304) arranged on the supporting plate (301), an output shaft of the pushing cylinder (304) is connected with a pushing plate (305), and the outer end face of the pushing plate (305) is an inclined face (306) with inclination;

the pressing part comprises a pressing block (307) arranged at the rear end of the flexible pressing block (302), and the pressing block (307) is connected with the flexible pressing block (302) through a pressing block mounting seat (308);

the lever part comprises a rotating arm (309), a rotating shaft (310) is arranged on the rotating arm (309), and the rotating shaft (310) is rotatably connected to the supporting plate (301);

both ends of the rotating arm (309) are respectively contacted with the end face of the press-fitting block (307) and the inclined face (306) of the pressing plate (305).

9. The battery module clamping platform of claim 8, wherein: the bottom of the press-fit block (307) is provided with a return spring (312), and the other end of the return spring (312) is fixedly connected with the supporting plate (301).

10. The battery module clamping platform of claim 9, wherein: the inner side of the reset spring (312) is provided with a positioning pin (313), and the bottom of the press-fit block (307) is provided with a positioning hole (314) for positioning the positioning pin (313).